VEHICLE CHASSIS
A vehicle chassis including a vehicle frame defining an inner space and being operable to switch between a first expanded state and a collapsed state, and a loading device mounted to the inner space and removably connected to the vehicle frame. The loading device defines a first loading surface when the vehicle frame is in the first expanded state, and the loading device defines a second loading surface that is smaller than the first loading surface when the vehicle frame is in the collapsed state.
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This application claims priority of Taiwanese Patent Applications No. 108103064 and No. 108103102, both filed on Jan. 28, 2019.
FIELDThe disclosure relates to an electric vehicle, and more particularly to a chassis of an electric vehicle.
BACKGROUNDA vehicle chassis of a conventional electric vehicle is commonly manufactured to be the same as that of a traditional vehicle, such that interior room of the electric vehicle is usually fixed and nonadjustable, thereby unable to satisfy various spatial demands of a user under difference circumstances. In addition, battery modules of the conventional electric vehicle are usually mounted underneath passenger seats or inside the luggage space, which are difficult to access for replacement.
SUMMARYTherefore, an object of the present disclosure is to provide a vehicle chassis that can alleviate at least one of the drawbacks of the prior art.
According to one aspect of the present disclosure, the vehicle chassis includes a vehicle frame that defines an inner space and that is operable to switch between a first expanded state and a collapsed state, and a loading device that is mounted to the inner space and that is removably connected to the vehicle frame. The loading device defines a first loading surface when the vehicle frame is in the first expanded state, and the loading device defines a second loading surface that is smaller than the first loading surface when the vehicle frame is in the collapsed state.
According to another aspect of the present disclosure, the vehicle chassis includes a vehicle frame that defines an inner space, and a loading device that includes a plurality of first loading boxes mounted to the inner space and removably connected to said vehicle frame, and a plurality of first battery modules removably and respectively disposed in the first loading boxes. The first loading boxes are permitted to be removably coupled to each other to cooperatively define a loading surface.
According to yet another aspect of the present disclosure, the vehicle chassis includes a vehicle frame that defines an inner space, and a loading device that includes four first loading boxes mounted to the inner space and removably connected to said vehicle frame, four first battery modules removably and respectively disposed in the first loading boxes, two second loading boxes, two second battery modules removably and respectively disposed in the second loading boxes, a third loading box, and a third battery module removably disposed in the third loading box. Each of the second loading boxes is permitted to be removably coupled between corresponding two of the first loading boxes, and the third loading box is permitted to be removably coupled among the first and second loading boxes to cooperatively define a loading surface.
According to still another aspect of the present disclosure, the vehicle chassis includes a vehicle frame that defines an inner space, and a loading device that includes four first loading boxes mounted to the inner space and removably connected to said vehicle frame, four first battery modules removably and respectively disposed in the first loading boxes, two second loading boxes, and two second battery modules removably and respectively disposed in the second loading boxes. Each of the second loading boxes is permitted to be removably coupled to each other and between corresponding two of the first loading boxes to cooperatively define a loading surface.
Other features and advantages of the disclosure will become apparent in the following detailed description of the embodiment with reference to the accompanying drawings, of which:
Before the disclosure is described in greater detail, it should be noted that where considered appropriate, reference numerals or terminal portions of reference numerals have been repeated among the figures to indicate corresponding or analogous elements, which may optionally have similar characteristics.
Referring to
Referring to
Each of the telescopic rods 12 has two opposite ends that are respectively and fixedly connected to corresponding two of the casing members 11, such that the casing members 11 and the telescopic rods 12 cooperatively define a substantially rectangular inner space 15 thereamong. Specifically, two pairs of the telescopic rods 12 are spaced apart from each other in the front-rear direction (X), extend in a lateral direction (Y) perpendicular to the front-rear direction (X) and respectively define two end openings 17 that are respectively at front and rear sides of the vehicle frame 10 and that are spaced apart in the front-rear direction (X), and the remaining two of the telescopic rods 12 are spaced apart from each other in the lateral direction (Y), extend in the front-rear direction (X), and respectively define two lateral openings 16 that are respectively at two opposite lateral sides of the vehicle frame 10 and that are spaced apart in the lateral direction (Y). In this embodiment, each of the telescopic rods 12 is an electric cylinder, and has a cylinder body 121, a motor 122, a rod body 123 that is permitted to telescopically extend through the cylinder body 121, a connecting plate 124 that is mounted to an end of the rod body 123 distal to the cylinder body 121, and a transmission member (not shown) that is mounted in the cylinder body 121 and that interconnects the motor 122 to the rod body 123. The cylinder body 121 and the connecting plate 124 of each of the telescopic rods 12 are respectively and fixedly connected to the vertical plates 113 of the corresponding two of the casing members 11 via fasteners such as bolts and nuts (as shown in
Referring to
The first loading assembly 2 includes four first loading boxes 21 respectively and removably connected to the casing members 11 of the vehicle frame 10, four first battery modules 23 respectively and removably disposed in the first loading boxes 21, and four first control modules 24 respectively assembled in the first loading boxes 21. In the embodiment, each of the first loading boxes 21 has a box body 211, a cover body 212, and a plurality of hinges 213. The box body 211 includes a substantially cubic box portion 214 that defines a storage space 215 therein for storing one of the first battery modules 23, and that has an open top end. The hinges 213 pivotally interconnect the box portion 214 and the cover body 212 so that the cover body 212 is permitted to enclose the storage space 215 by pivotally covering the top end of the box portion 214.
Each of the first loading boxes 21 includes a plurality of first guiding tongues 216 protruding from one of lateral sides thereof proximate to center of the vehicle chassis 100 and extending in the front-rear direction (X), and a plurality of second guiding tongues 217 protruding from one of front and rear sides thereof proximate to the center of the vehicle chassis 100 and extending in the lateral direction (Y). The first guiding tongues 216 are spaced apart from each other in an up-down direction (Z) perpendicular to both the front-rear direction (X) and the lateral direction (Y) to define a plurality of first guiding grooves 218, and the second guiding tongues 217 are spaced apart from each other in the up-down direction (Z) to define a plurality of second guiding grooves 219. Each of the first guiding tongues 216 is permitted to be slidably connected to a corresponding one of the first guiding grooves 218, and each of the second guiding tongues 217 is permitted to be slidably connected to a corresponding one of the second guiding grooves 219, such that each of the first loading boxes 21 is permitted to be removably coupled to adjacent ones of the first loading boxes 21.
In the embodiment, of the four first loading boxes 21, each of leftmost two includes three of the first guiding tongues 216 and two of the first guiding grooves 218, each of rightmost two includes two of the first guiding tongues 216 and three of the first guiding grooves 218, each of frontmost two includes two of the second guiding tongues 217 and three of the second guiding grooves 219, and each of rearmost two includes three of the second guiding tongues 217 and two of the second guiding grooves 219. The first loading boxes 21 are disposed between the the top and bottom plates 111, 112 of the respective ones of the casing members 11, and are removably connected thereto via fasteners such as screws.
The first loading boxes 21 of the first loading assembly 2 are operable to be driven by the casing members 11 of the vehicle frame 10 to switch between a separated state (see
The box body 211 of each of the first loading boxes 21 includes two first through hole units 222 that are spatially communicated with the storage space 215. For each of the first loading boxes 21, one of the first through hole units 222 is disposed on the side of the box body 211 having the first guiding tongues and grooves 216, 218, and the other one of the first through hole units 222 is disposed on the side of the box body 211 having the second guiding tongues and grooves 217, 219. Each of the first through hole units 222 has two first through holes 223 that are spaced apart in the up-down direction (Z). In the embodiment, the first through holes 223 of each of the first through hole units 222 are respectively disposed proximate to top and bottom ends of the box body 221, and the first through hole units 222 of each of the first loading boxes 21 are respectively registered with the first through hole units 222 of the adjacent ones of the first loading boxes 21. Each of the first through holes 223 has an enlarged end section 225 that is spatially communicated to the storage space 215, a shrunk end section 226 that is spatially communicated to an external environment, a shoulder section 227 that interconnects the enlarged end section 225 and the shrunk end section 226.
Each of the first battery modules 23 includes a first battery 231 and two first electrode units 232 that respectively extend through the first through hole units 222. The first battery 231 is mounted in the storage space 215 of the box body 211 of a respective one of the first loading boxes 21. Each of the first electrode units 232 has two first wires 234 connected to the first battery 231, a positive electrode 235 connected to an end of one of the first wires 234, and a negative electrode 236 connected to an end of the other one of the first wires 234. The positive and negative electrodes 235, 236 are made of metallic materials that are both magnetic and conductive. Each of the first wires 234 of the first electrode units 232 extends through a respective one of the first through holes 223 of the first through hole units 222, such that the positive electrode 235 extends into a top one of the first through holes 223, and the negative electrode 236 extends into a bottom one of the first through holes 223. For each of the first through holes 223, after one of the positive and negative electrodes 235, 236 extends thereinto, a resilient member 228 and an abutment member 229 are assembled thereto to ensure that the one of the positive and negative electrodes 235, 236 is positioned in the shrunk end section 226 thereof to remain exposed to the external environment. Specifically, the abutment member 229 is fixedly mounted to an end of the enlarged end section 225 distal to the shrunk end section 226, and the resilient member 228 is disposed in the enlarged end section 225 and has one end resiliently abutting against the abutment member 229, and the other end abutting against the one of the positive and negative electrodes 235, 236 to push the one of the positive and negative electrodes 235, 236 against the shoulder section 227. When the vehicle frame 10 is in the collapsed state and the first loading assembly 2 is in the assembled state, the first battery modules 23 are electrically connected to each other in parallel. Specifically, the two positive electrodes 235 of each of the first battery modules 23 are respectively and electrically connected to the positive electrodes 235 of two adjacent ones of the first battery modules 23, and the two negative electrodes 236 of each of the first battery modules 23 are respectively and electrically connected to the negative electrodes 236 of two adjacent ones of the first battery modules 23. The magnetic feature of the positive and negative electrodes 235, 236 ensures stable electric connection between corresponding two of the positive electrodes 235 and between corresponding two of the negative electrodes 236.
For each of the first loading boxes 21, the first control module 24 is mounted in the storage space 215, and includes a first circuit board 241 electrically connected to the first battery 231 and a first wireless chip 242 mounted to the first circuit board 241. The first wireless chip 242 may conduct wireless communication via means such as wifi, bluetooth, or NFC. The first control module 24 is permitted to be signally connected to a communication device (not shown) such as a smartphone, a tablet, or a user interface in the electric vehicle via the first wireless chip 242 for a user to monitor stored electricity in the first battery 231.
The second loading assembly 3 includes two second loading boxes 31, two second battery modules 33 respectively and removably disposed in the second loading boxes 31, a third loading box 34, three third battery modules 36 removably disposed in the third loading box 34, two second control modules 37 respectively assembled in the second loading boxes 31, and a third control module 38 assembled in the third loading box 34. In the embodiment, each of the second loading boxes 31 has a box body 311, a cover body 312, a plurality of hinges 313, and a first handle 314. The box body 311 includes a substantially cubic box portion 315 that defines a storage space 316 therein for storing one of the second battery modules 33, and that has an open top end. The hinges 313 pivotally interconnect the box portion 315 and the cover body 312 so that the cover body 312 is permitted to enclose the storage space 316 by pivotally covering the top end of the box portion 315.
Each of the second loading boxes 31 includes a plurality of third guiding tongues 317 protruding from one of lateral sides thereof proximate to center of the vehicle chassis 100 and extending in the front-rear direction (X), and a plurality of fourth guiding tongues 318 protruding from front and rear sides thereof and extending in the lateral direction (Y). The third guiding tongues 317 are spaced apart in the up-down direction (Z) to define a plurality of third guiding grooves 319, and the fourth guiding tongues 318 at each side of the second loading box 31 are spaced apart in the up-down direction (Z) to define a plurality of fourth guiding grooves 320. Each of the fourth guiding tongues 318 is permitted to be slidably connected to a corresponding one of the second guiding grooves 219, and each of the second guiding tongues 217 is permitted to be slidably connected to a corresponding one of the fourth guiding grooves 320, such that each of the second loading boxes 31 is permitted to be removably coupled between corresponding two of the first loading boxes 21.
For each of the second loading boxes 31, the first handle 314 is mounted to a lateral outer side of the box portion 315. The user may easily pull each of the second loading boxes 31, via the first handle 314 thereof, to slide in the lateral direction (Y) and to be respectively uncoupled from the corresponding two of the first loading boxes 21 through a respective one of the lateral openings 16, or vice-versa.
In the embodiment, for each of the second loading boxes 31, the front side thereof includes three of the fourth guiding tongues 318 and two of the fourth guiding grooves 320, and the rear side thereof includes two of the fourth guiding tongues 318 and three of the fourth guiding grooves 320. However, the left one of the second loading boxes 31 includes three of the third guiding tongues 317 and two of the third guiding grooves 319, and the right one of the second loading boxes 31 includes two of the third guiding tongues 317 and three of the third guiding grooves 319.
The box body 311 of each of the second loading boxes 31 includes three second through hole units 321 that are respectively disposed on front, rear, center-facing lateral sides thereof and that are spatially communicated with the storage space 316. Each of the second through hole units 321 has two second through holes 322 that are spaced apart in the up-down direction (Z). In the embodiment, the second through holes 322 of each of the second through hole units 321 are respectively disposed proximate to top and bottom ends of the box body 311, and the second through hole units 321 disposed on the front and rear sides of each of the second loading boxes 31 are respectively registered with the first through hole units 222 of the adjacent ones of the first loading boxes 21. Each of the second through holes 322 has an enlarged end section 324 that is spatially communicated to the storage space 316, a shrunk end section 325 that is spatially communicated to an external environment, a shoulder section 326 that interconnects the enlarged end section 324 and the shrunk end section 325.
Referring back to
For each of the second loading boxes 31, the second control module 37 is mounted in the storage space 316 and includes a second circuit board 371 electrically connected to the second battery 331 and a second wireless chip 372 mounted to the second circuit board 371. The second wireless chip 372 may conduct wireless communication via means such as wifi, bluetooth, or NFC. The second control module 37 is permitted to be signally connected to the communication device via the second wireless chip 372 for the user to monitor stored electricity in the second battery 331.
Referring to
The third loading box 34 includes a plurality of fifth guiding tongues 347 extending in the front-rear direction (X) and protruding from lateral sides thereof. The fifth guiding tongues 347 at each side of the third loading box 34 are spaced apart in the up-down direction (Z) to define a plurality of fifth guiding grooves 348. Each of the fifth guiding tongues 347 is permitted to be slidably connected to corresponding ones of the first and third guiding grooves 218, 319, and each of the first and third guiding tongues 216, 317 is permitted to be slidably connected to a corresponding one of the fifth guiding grooves 348, such that the third loading box 34 is permitted to be removably coupled among the first and second loading boxes 21,31.
The second handle 344 is mounted to a front side of the box portion 345. The user may easily pull the third box 34, via the second handle 344, to slide in the front-rear direction (X) and to be uncoupled from the first and second loading boxes 21, 31 through one of the end openings 17 (as seen in
In the embodiment, the left side of the third loading box 34 includes two of the fifth guiding tongues 347 and three of the fifth guiding grooves 348, and the right side thereof includes three of the fifth guiding tongues 347 and two of the fifth guiding grooves 348.
The box body 341 of the third loading box 34 includes six third through hole units 349 that are spatially communicated with the storage space 346. Each of the third through hole units 349 has two third through holes 350 that are spaced apart in the up-down direction (Z). Three of the third through hole units 349 are disposed on the left side of the box body 341, and the other three of the third through hole units 349 are disposed on the right side of the box body 341. In the embodiment, the third through holes 350 of each of the third through hole units 349 are respectively disposed proximate to top and bottom ends of the box body 341, four of the third through hole units 349 of the third loading box 34 are respectively registered with the first through hole units 222 at the center-facing lateral sides of the first loading boxes 21, and two of the third through hole units 349 of the third loading box 34 are respectively registered with the second through hole units 321 at the center-facing lateral sides of the second loading boxes 31. Each of the third through holes 350 has an enlarged end section 352 that is spatially communicated to the storage space 346, a shrunk end section 353 that is spatially communicated to an external environment, and a shoulder section 354 that interconnects the enlarged end section 352 and the shrunk end section 353.
Referring to
The third control module 38 is mounted in the storage space 346 and includes a third circuit board 381 electrically connected to the third battery 361 and a third wireless chip 382 mounted to the second circuit board 371. The second wireless chip 382 may conduct wireless communication via means such as wifi, bluetooth, or NFC. The third control module 38 is permitted to be signally connected to the communication device via the third wireless chip 382 for the user to monitor stored electricity in the third battery 361.
Referring to
Referring back to
Referring to
Referring to
Referring to
Referring to
Once the vehicle frame 10 is in the collapsed state, the motor 122 stops. In the assembled state, each of the first guiding tongues 216 is slidably connected to the corresponding one of the first guiding grooves 218, and each of the second guiding tongues 217 is slidably connected to the corresponding one of the second guiding grooves 219, such that the first loading boxes 21 are coupled to each other to define a second loading surface 202 that is smaller than the first loading surface 201. In comparison to the first loading surface 201, the second loading surface 202 is more optimal for supporting a vehicle body of a smaller size, and satisfies demand of a single passenger when extra passenger space is not needed. After the vehicle frame 10 has been switched to the collapsed state, the top strut 432 of each of the jacks 43 move upwardly relative to the vehicle frame 10 so that the wheels 13 are back to be in contact with the ground 5 again (
Referring to
Referring to
Referring to
Each of the first loading boxes 21 further includes a first movement module 26 that is mounted in the first guiding tongues 216 and the first guiding grooves 218, and a second movement module 27 that is mounted in the second guiding tongues 217 and the second guiding grooves 219.
Each of the first movement modules 26 includes a plurality of first horizontal coils 261, a plurality of first vertical coils 262 and plurality of first transport wheels 263. Each of the first horizontal coils 261 extends in the front-rear direction (X), is mounted to and is flush with a top surface 2161 of a corresponding one of the first guiding tongues 216 that is for bearing a corresponding one of the fifth guiding tongues 347. The first vertical coils 262 are circular and are disposed in vertical surfaces 2181 of the first guiding grooves 218. The first vertical coils 262 in each of the first guiding grooves 218 are spaced apart from each other in the front-rear direction (X). The first transport wheels 263 are mounted to the corresponding first guiding tongues 216 that are for bearing the corresponding fifth guiding tongues 347. The first transport wheels 263 in each of the first guiding tongues 216 are spaced apart in the front-rear direction (X).
Each of the second movement modules 27 includes a plurality of second horizontal coils 271, a plurality of second vertical coils 272 and plurality of second transport wheels 273. Each of the second horizontal coils 271 extends in the lateral direction (Y), is mounted to and is flush with a top surface 2171 of a corresponding one of the second guiding tongues 217 that is for bearing a corresponding one of the fourth guiding tongues 318. The second vertical coils 272 are circular and are disposed in vertical surfaces 2191 of the second guiding grooves 219. The second vertical coils 272 in each of the second guiding grooves 219 are spaced apart from each other in the lateral direction (Y). The second transport wheels 273 are mounted to the corresponding second guiding tongues 217 that are for bearing the corresponding fourth guiding tongues 318. The second transport wheels 273 in each of the second guiding tongues 217 are spaced apart in the lateral direction (Y).
Referring to
Referring back to
Each of the fourth movement modules 62 includes a plurality of fourth horizontal coils 621 and a plurality of fourth vertical coils 622. Each of the fourth horizontal coils 621 extends in the lateral direction (Y), is mounted to and is flush with a bottom surface 3181 of a corresponding one of the fourth guiding tongues 318 that is supported by the second transport wheels 273. Each of the fourth horizontal coils 621 are disposed above a corresponding one of the second horizontal coils 271. Each of the fourth vertical coils 622 is circular, is mounted to a vertical surface 3182 of a corresponding one the fourth guiding tongues 318, and is operable to be registered with one of the second vertical coils 272 in the corresponding second guiding groove 219. In this embodiment, each of the fourth vertical coils 622 is mounted to the corresponding one of the fourth guiding tongues 318 at an end thereof proximate to the third guiding grooves 319.
Referring to
Referring back to
Referring to
Referring to
After being powered up, the second and fourth horizontal coils 271, 621 have the same polarity, which generates repelling magnetic force for lifting the fourth guiding tongues 318 to slide easily, and the second and fourth vertical coils 272, 626 have opposite polarities, which generates attracting magnetic force therebetween for pulling the second loading box 31 in the outward direction. By combining the magnetic forces with the rotation of the second transport wheels 273, the fourth guiding tongues 318 of the second loading box 31 are driven to move outwardly, such that the second loading box 31 is automatically pushed outwardly for the user to access. By reversing the order of the abovementioned operations, the second loading box 31 is reverted to be coupled between the corresponding two of the first loading boxes 21 again.
Referring to
After being powered up, the first, third and fifth horizontal coils horizontal coils 261, 611, 631 have the same polarity, which generates repelling magnetic force for lifting the third guiding tongues 347 to slide easily, and the first and third vertical coils 262, 612 have polarity opposite to that of the fifth vertical coils 632, which generates attracting magnetic force thereamong for pulling the third loading box 34 in the outward direction. By combining the magnetic forces with the rotation of the third transport wheels 613, the fifth guiding tongues 347 of the third loading box 34 are driven to move outwardly, such that the third loading box 34 is automatically pushed outwardly for the user to access. By reversing the order of the abovementioned operations, the third loading box 34 is reverted to be coupled among the first and second loading boxes 21, 31 again.
Referring to
Overall, by operating the vehicle frame 10 to switch between the various states disclosed above and by the design of the first and second loading assemblies 2, 3, the electric chassis 100 of the embodiments is suitable for use in different driving circumstances. In addition, the design for uncoupling the second and third loading boxes 31, 34 from the first loading boxes 21 through the openings of the vehicle frame 10 provides easier access thereto for replacement and repair of the batteries therein.
In the description above, for the purposes of explanation, numerous specific details have been set forth in order to provide a thorough understanding of the embodiment. It will be apparent, however, to one skilled in the art, that one or more other embodiments maybe practiced without some of these specific details. It should also be appreciated that reference throughout this specification to “one embodiment,” “an embodiment,” an embodiment with an indication of an ordinal number and so forth means that a particular feature, structure, or characteristic may be included in the practice of the disclosure. It should be further appreciated that in the description, various features are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure and aiding in the understanding of various inventive aspects, and that one or more features or specific details from one embodiment may be practiced together with one or more features or specific details from another embodiment, where appropriate, in the practice of the disclosure.
While the disclosure has been described in connection with what is considered the exemplary embodiment, it is understood that this disclosure is not limited to the disclosed embodiment but is intended to cover various arrangements included within the spirit and scope of the broadest interpretation so as to encompass all such modifications and equivalent arrangements.
Claims
1. A vehicle chassis comprising:
- a vehicle frame defining an inner space and being operable to switch between a first expanded state and a collapsed state; and
- a loading device mounted to said inner space and removably connected to said vehicle frame, said loading device defining a first loading surface when said vehicle frame is in the first expanded state, and said loading device defining a second loading surface that is smaller than said first loading surface when said vehicle frame is in the collapsed state.
2. The vehicle chassis as claimed in claim 1, wherein:
- said loading device includes a first loading assembly that is to be removably connected to said vehicle frame, and a second loading assembly that is to be removably coupled to said first loading assembly;
- when said vehicle frame is in the first expanded state, said first loading assembly is in a separated state, and defines a mounting space for said second loading assembly to be mounted thereto and to be coupled to said first loading assembly, and said second loading assembly cooperates with said first loading assembly to define said first loading surface; and
- when said vehicle frame is in the collapsed state, said second loading assembly is separated from said first loading assembly, and said first loading assembly is in an assembled state and defines said second loading surface.
3. The vehicle chassis as claimed in claim 2, wherein:
- said first loading assembly includes a plurality of first loading boxes removably connected to said vehicle frame, and a plurality of first battery modules removably and respectively disposed in said first loading boxes, each of said first loading boxes being permitted to be removably coupled to adjacent ones of said first loading boxes;
- when said first loading assembly is in the separated state, said first loading boxes are spaced apart from each other to define said mounting space thereamong; and
- when said first loading assembly is in the assembled state, said first loading boxes are coupled to each other to cooperatively define said second loading surface.
4. The vehicle chassis as claimed in claim 3, wherein:
- said vehicle frame is permitted to be telescopic in at least a front-rear direction (X);
- said vehicle frame is formed with at least one lateral opening that is registered with said mounting space;
- said second loading assembly includes at least one second loading box and at least one second battery module removably disposed in said at least one second loading box, said at least one second loading box being permitted to be removably coupled between corresponding two of said first loading boxes; and
- when said vehicle frame is in the first expanded state, said second loading box is permitted to be uncoupled from said first loading boxes in a lateral direction (Y) perpendicular to the front-rear direction (X) through said lateral opening.
5. The vehicle chassis as claimed in claim 4, wherein:
- said vehicle frame is formed with two of said lateral openings respectively at two opposite sides thereof, said lateral openings being spaced apart in the lateral direction (Y);
- said second loading assembly includes two of said second loading boxes and two of said second battery modules removably and respectively disposed in said second loading boxes; and
- when said vehicle frame is in the first expanded state, each of said second loading boxes is permitted to be respectively uncoupled from corresponding two of said first loading boxes through a respective one of said lateral openings.
6. The vehicle chassis as claimed in claim 5, wherein:
- said vehicle frame is telescopic in the front-rear direction (X) and the lateral direction (Y), such that said vehicle frame is operable to switch between the first expanded state and the collapsed state;
- said vehicle frame is substantially rectangular, includes four casing members respectively disposed at four corners of said vehicle frame, and is further formed with an end opening that is permitted to be registered to said mounting space;
- said first loading assembly includes four of said first loading boxes removably and respectively connected to said casing members;
- said second loading assembly further includes a third loading box and at least one third battery module removably disposed in said third loading box, said third loading box being permitted to be removably coupled among said first loading boxes and said second loading boxes; and
- when said vehicle frame is in the first expanded state, said first, second and third loading boxes cooperatively define said first loading surface, and said third loading box is permitted to be uncoupled from said first and second loading boxes in the front-rear direction (X) through said end opening.
7. The vehicle chassis as claimed in claim 6, wherein:
- said first, second and third battery modules are electrically connected to each other in parallel when said vehicle frame is in the first expanded state; and
- said first battery modules are electrically connected to each other in parallel when said vehicle frame is in the collapsed state.
8. The vehicle chassis as claimed in claim 7, wherein:
- each of said first loading boxes includes two first through hole units, each of said first battery modules including two first electrode units that respectively extend through said first through hole units;
- each of said second loading boxes includes three second through hole units, each of said second battery modules including three second electrode units that respectively extend through said second through hole units;
- said third loading box includes six third through hole units, said second loading assembly including three of said third battery modules that are removably disposed in said third loading box, each of said third battery modules including two third electrode units that respectively extend through corresponding two of said third through hole units; and
- when said vehicle frame is in the first expanded state, each of said third electrode units of one of said third battery modules is electrically connected to one of said second electrode units of a respective one of said second battery modules, each of said third electrode units of the remaining two of said third battery modules is electrically connected to a corresponding one of said first electrode units, and the remaining two of said second electrode units of each of said second battery modules are respectively and electrically connected to the corresponding first electrode units.
9. The vehicle chassis as claimed in claim 6, wherein:
- each of said first loading boxes includes a plurality of first guiding tongues extending in the front-rear direction (X), and a plurality of second guiding tongues extending in the lateral direction (Y), said first guiding tongues being spaced apart from each other in an up-down direction (Z) perpendicular to both the front-rear direction (X) and the lateral direction (Y) to define a plurality of first guiding grooves, and said second guiding tongues being spaced apart from each other in the up-down direction (Z) to define a plurality of second guiding grooves;
- each of said second loading boxes includes a plurality of third guiding tongues extending in the front-rear direction (X) and being spaced apart in the up-down direction (Z) to define a plurality of third guiding grooves, and a plurality of fourth guiding tongues extending in the lateral direction (Y) and disposed at two opposite sides of said second loading box in such a manner that said fourth guiding tongues at each side of said second loading box are spaced apart in the up-down direction (Z) to define a plurality of fourth guiding grooves;
- said third loading box includes a plurality of fifth guiding tongues extending in the front-rear direction (X) and disposed at two opposite sides of said third loading box in such a manner that said fifth guiding tongues at each side of said third loading box are spaced apart in the up-down direction (Z) to define a plurality of fifth guiding grooves; and
- each of said first and third guiding tongues is permitted to be sildably connected to a corresponding one of said fifth guiding grooves, each of said second guiding tongues is permitted to be slidably connected to a corresponding one of said fourth guiding grooves, each of said fourth guiding tongues is permitted to be slidably connected to a corresponding one of said second guiding grooves, and each of said fifth guiding tongues is permitted to be slidably connected to corresponding ones of said first and third guiding grooves.
10. The vehicle chassis as claimed in claim 9, wherein:
- each of said first loading boxes further includes a first movement module that is mounted in said first guiding tongues and said first guiding grooves, and a second movement module that is mounted in said second guiding tongues and said second guiding grooves;
- each of said second loading boxes further includes a third movement module that is mounted in said third guiding tongues and said third guiding grooves, and two fourth movement modules that are disposed respectively at the opposite sides of said second loading boxes and that are mounted in said corresponding fourth guiding tongues and fourth guiding grooves, each of said fourth movement modules being permitted to cooperate with said corresponding second movement module to co-facilitate movement of each of said second loading boxes relative to the corresponding two of said first loading boxes in the lateral direction (Y); and
- said third loading box further includes two fifth movement modules that are disposed respectively at the opposite sides of said third loading box and that are mounted in said corresponding fifth guiding tongues and fifth guiding grooves, each of said fifth movement modules being permitted to cooperate with said corresponding first and third movement modules to co-facilitate movement of said third loading box relative to said first and second loading boxes in the front-rear direction (X).
11. The vehicle chassis as claimed in claim 10, wherein:
- each of said first movement modules of said first loading boxes includes a plurality of first horizontal coils and a plurality of first vertical coils, each of said first horizontal coils being mounted to a corresponding one of said first guiding tongues that is forbearing a corresponding one of said fifth guiding tongues, said first vertical coils being disposed in said first guiding grooves, and said first vertical coils in each of said first guiding grooves being spaced apart from each other in the front-rear direction (X);
- each of said second movement modules of said first loading boxes includes a plurality of second horizontal coils and a plurality of second vertical coils, each of said second horizontal coils being mounted to a corresponding one of said second guiding tongues that is for bearing a corresponding one of said fourth guiding tongues, said second vertical coils being disposed in said second guiding grooves, and said second vertical coils in each of said second guiding grooves being spaced apart from each other in the lateral direction (Y);
- each of said third movement modules of said second loading boxes includes a plurality of third horizontal coils and a plurality of third vertical coils, each of said third horizontal coils being mounted to a corresponding one of said third guiding tongues that is forbearing a corresponding one of said fifth guiding tongues, said third vertical coils being disposed in said third guiding grooves, and said third vertical coils in each of said third guiding grooves being space apart from each other in the front-rear direction (X);
- each of said fourth movement modules of said second loading boxes includes a plurality of fourth horizontal coils and a plurality of fourth vertical coils, each of said fourth horizontal coils and each of said fourth vertical coils being mounted to a corresponding one of said fourth guiding tongues, each of said fourth horizontal coils being disposed above a corresponding one of said second horizontal coils, and each of said fourth vertical coils being operable to be registered with one of said second vertical coils in said second guiding grooves;
- each of said fifth movement modules includes a plurality of fifth horizontal coils and a plurality of fifth vertical coils, each of said fifth horizontal coils and each of said fifth vertical coils being mounted to a corresponding one of said fifth guiding tongues, each of said fifth horizontal coils being disposed above corresponding ones of said first and third horizontal coils, and each of said fifth vertical coils being operable to be registered with one of said first vertical coils in said first guiding grooves;
- said first loading assembly further includes a plurality of first control modules respectively assembled in said first loading boxes, each of said first control modules being operable to power up said first horizontal and vertical coils and said second horizontal and vertical coils for generating magnetic force;
- said second loading assembly further includes two second control modules respectively assembled in said second loading boxes and a third control module assembled in said third loading box, each of said second control modules being operable to power up said third horizontal and vertical coils and said fourth horizontal and vertical coils for generating magnetic force, and said third control module being operable to power up said fifth horizontal and vertical coils for generating magnetic force; and
- after being powered up, said first, third and fifth horizontal coils have the same polarity, said second and fourth horizontal coils have the same polarity, said first and third vertical coils have polarity opposite to that of said fifth vertical coils, and said second vertical coils have polarity opposite to that of said fourth vertical coils.
12. The vehicle chassis as claimed in claim 11, wherein:
- each of said first movement modules further includes a plurality of first transport wheels that are mounted to said corresponding first guiding tongues forbearing said corresponding fifth guiding tongues;
- each of said second movement modules further includes a plurality of second transport wheels that are mounted to said corresponding second guiding tongues for bearing said corresponding fourth guiding tongues;
- each of said third movement modules further includes a plurality of third transport wheels that are mounted to said corresponding third guiding tongues forbearing said corresponding fifth guiding tongues; and
- each of said first control modules is operable to control movement of said fifth guiding tongues via rotation of said first transport wheels and to control movement of said fourth guiding tongues via rotation of said second transport wheels, and each of said second control modules is operable to control movement of said fifth guiding tongues via rotation of said third transport wheels.
13. The vehicle chassis as claimed in claim 6, wherein:
- said vehicle frame further includes four pairs of telescopic rods, each pair of which fixedly interconnects corresponding two of said casing members;
- two pairs of said telescopic rods are spaced apart in the lateral direction (Y), are telescopic in the front-rear direction (X), and respectively define two of said lateral openings; and
- the other two pairs of said telescopic rods are spaced apart in the front-rear direction (X), are telescopic in the lateral direction (Y), one of which defines said end opening.
14. The vehicle chassis as claimed in claim 6, further comprising a lifting device, wherein:
- said vehicle frame further includes four wheels respectively connected to said casing members and permitted to be in contact with ground;
- said lifting device is for lifting said vehicle frame such that said wheels are not permitted to be in contact with the ground, and includes four jacks respectively mounted to said casing members, each of said jacks having a jack main body and a top strut that telescopically extends from a bottom of said jack main body and that has a contact member disposed at a bottom thereof, said contact member being a freely-rotatable ball; and
- said top strut is operable to move between a base position, where said contact member is disposed higher than bottom of said wheels, and an extended position, where said contact member is disposed lower than the bottom of said wheels.
15. The vehicle chassis as claimed in claim 1, wherein said vehicle frame is operable to be further switched to a second expanded state, in which said loading device defines a third loading surface that is smaller than said first loading surface and that is larger than said second loading surface.
16. The vehicle chassis as claimed in claim 15, wherein:
- said loading device includes four first loading boxes removably connected to said vehicle frame, and two second loading boxes;
- said first loading boxes are permitted to be removably coupled to each other to define said second loading surface, and each of said second loading boxes is permitted to be removably coupled between corresponding two of said first loading boxes;
- when said vehicle frame is in the second expanded state, each of said second loading boxes is removably coupled to each other and between the corresponding two of said first loading boxes to cooperatively define said third loading surface; and
- when said vehicle frame is in the collapsed state, each of said second loading boxes is separated from each other and from the corresponding two of said first loading boxes.
17. A vehicle chassis comprising:
- a vehicle frame defining an inner space; and
- a loading device including a plurality of first loading boxes mounted to said inner space and removably connected to said vehicle frame, and a plurality of first battery modules removably and respectively disposed in said first loading boxes, said first loading boxes being permitted to be removably coupled to each other to cooperatively define a loading surface.
18. A vehicle chassis comprising:
- a vehicle frame defining an inner space; and
- a loading device including four first loading boxes mounted to said inner space and removably connected to said vehicle frame, four first battery modules removably and respectively disposed in said first loading boxes, two second loading boxes, two second battery modules removably and respectively disposed in said second loading boxes, a third loading box, and a third battery module removably disposed in said third loading box;
- wherein, each of said second loading boxes is permitted to be removably coupled between corresponding two of said first loading boxes, said third loading box is permitted to be removably coupled among said first and second loading boxes to cooperatively define a loading surface.
19. A vehicle chassis comprising:
- a vehicle frame defining an inner space; and
- a loading device including four first loading boxes mounted to said inner space and removably connected to said vehicle frame, four first battery modules removably and respectively disposed in said first loading boxes, two second loading boxes, and two second battery modules removably and respectively disposed in said second loading boxes;
- wherein, each of said second loading boxes is permitted to be removably coupled to each other and between corresponding two of said first loading boxes to cooperatively define a loading surface.
Type: Application
Filed: Nov 13, 2019
Publication Date: Jul 30, 2020
Patent Grant number: 11148519
Applicant: National Taiwan Normal University (Taipei City)
Inventors: Yi-Hsuan HUNG (Taipei City), Ping-Hung SHIH (Taipei City), Li-Fan LIU (Taipei City), Yi-Ya LIAO (Taipei City), Kan-Yuan TIAN (Taipei City)
Application Number: 16/682,916